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Keras Tuner

A hyperparameter tuner for Keras, specifically for tf.keras with TensorFlow 2.0.

Full documentation and tutorials available on the Keras Tuner website.

Installation

Requirements:

  • Python 3.6
  • TensorFlow 2.0

Install latest release:

pip install -U keras-tuner

Install from source:

git clone https://github.com/keras-team/keras-tuner.git
cd keras-tuner
pip install .

Usage: the basics

Here's how to perform hyperparameter tuning for a single-layer dense neural network using random search.

First, we define a model-building function. It takes an argument hp from which you can sample hyperparameters, such as hp.Int('units', min_value=32, max_value=512, step=32) (an integer from a certain range).

This function returns a compiled model.

from tensorflow import keras
from tensorflow.keras import layers
from kerastuner.tuners import RandomSearch


def build_model(hp):
    model = keras.Sequential()
    model.add(layers.Dense(units=hp.Int('units',
                                        min_value=32,
                                        max_value=512,
                                        step=32),
                           activation='relu'))
    model.add(layers.Dense(10, activation='softmax'))
    model.compile(
        optimizer=keras.optimizers.Adam(
            hp.Choice('learning_rate',
                      values=[1e-2, 1e-3, 1e-4])),
        loss='sparse_categorical_crossentropy',
        metrics=['accuracy'])
    return model

Next, instantiate a tuner. You should specify the model-building function, the name of the objective to optimize (whether to minimize or maximize is automatically inferred for built-in metrics), the total number of trials (max_trials) to test, and the number of models that should be built and fit for each trial (executions_per_trial).

Available tuners are RandomSearch and Hyperband.

Note: the purpose of having multiple executions per trial is to reduce results variance and therefore be able to more accurately assess the performance of a model. If you want to get results faster, you could set executions_per_trial=1 (single round of training for each model configuration).

tuner = RandomSearch(
    build_model,
    objective='val_accuracy',
    max_trials=5,
    executions_per_trial=3,
    directory='my_dir',
    project_name='helloworld')

You can print a summary of the search space:

tuner.search_space_summary()

Then, start the search for the best hyperparameter configuration. The call to search has the same signature as model.fit().

tuner.search(x, y,
             epochs=5,
             validation_data=(val_x, val_y))

Here's what happens in search: models are built iteratively by calling the model-building function, which populates the hyperparameter space (search space) tracked by the hp object. The tuner progressively explores the space, recording metrics for each configuration.

When search is over, you can retrieve the best model(s):

models = tuner.get_best_models(num_models=2)

Or print a summary of the results:

tuner.results_summary()

You will also find detailed logs, checkpoints, etc, in the folder my_dir/helloworld, i.e. directory/project_name.

The search space may contain conditional hyperparameters

Below, we have a for loop creating a tunable number of layers, which themselves involve a tunable units parameter.

This can be pushed to any level of parameter interdependency, including recursion.

Note that all parameter names should be unique (here, in the loop over i, we name the inner parameters 'units_' + str(i)).

def build_model(hp):
    model = keras.Sequential()
    for i in range(hp.Int('num_layers', 2, 20)):
        model.add(layers.Dense(units=hp.Int('units_' + str(i),
                                            min_value=32,
                                            max_value=512,
                                            step=32),
                               activation='relu'))
    model.add(layers.Dense(10, activation='softmax'))
    model.compile(
        optimizer=keras.optimizers.Adam(
            hp.Choice('learning_rate', [1e-2, 1e-3, 1e-4])),
        loss='sparse_categorical_crossentropy',
        metrics=['accuracy'])
    return model

You can use a HyperModel subclass instead of a model-building function

This makes it easy to share and reuse hypermodels.

A HyperModel subclass only needs to implement a build(self, hp) method.

from kerastuner import HyperModel


class MyHyperModel(HyperModel):

    def __init__(self, classes):
        self.classes = classes

    def build(self, hp):
        model = keras.Sequential()
        model.add(layers.Dense(units=hp.Int('units',
                                            min_value=32,
                                            max_value=512,
                                            step=32),
                               activation='relu'))
        model.add(layers.Dense(self.classes, activation='softmax'))
        model.compile(
            optimizer=keras.optimizers.Adam(
                hp.Choice('learning_rate',
                          values=[1e-2, 1e-3, 1e-4])),
            loss='sparse_categorical_crossentropy',
            metrics=['accuracy'])
        return model


hypermodel = MyHyperModel(classes=10)

tuner = RandomSearch(
    hypermodel,
    objective='val_accuracy',
    max_trials=10,
    directory='my_dir',
    project_name='helloworld')

tuner.search(x, y,
             epochs=5,
             validation_data=(val_x, val_y))

Keras Tuner includes pre-made tunable applications: HyperResNet and HyperXception

These are ready-to-use hypermodels for computer vision.

They come pre-compiled with loss="categorical_crossentropy" and metrics=["accuracy"].

from kerastuner.applications import HyperResNet
from kerastuner.tuners import Hyperband

hypermodel = HyperResNet(input_shape=(128, 128, 3), classes=10)

tuner = Hyperband(
    hypermodel,
    objective='val_accuracy',
    max_epochs=40,
    directory='my_dir',
    project_name='helloworld')

tuner.search(x, y,
             validation_data=(val_x, val_y))

You can easily restrict the search space to just a few parameters

If you have an existing hypermodel, and you want to search over only a few parameters (such as the learning rate), you can do so by passing a hyperparameters argument to the tuner constructor, as well as tune_new_entries=False to specify that parameters that you didn't list in hyperparameters should not be tuned. For these parameters, the default value gets used.

from kerastuner import HyperParameters

hypermodel = HyperXception(input_shape=(128, 128, 3), classes=10)

hp = HyperParameters()
# This will override the `learning_rate` parameter with your
# own selection of choices
hp.Choice('learning_rate', values=[1e-2, 1e-3, 1e-4])

tuner = Hyperband(
    hypermodel,
    hyperparameters=hp,
    # `tune_new_entries=False` prevents unlisted parameters from being tuned
    tune_new_entries=False,
    objective='val_accuracy',
    max_epochs=40,
    directory='my_dir',
    project_name='helloworld')

tuner.search(x, y,
             validation_data=(val_x, val_y))

Want to know what parameter names are available? Read the code.

About parameter default values

Whenever you register a hyperparameter inside a model-building function or the build method of a hypermodel, you can specify a default value:

hp.Int('units',
       min_value=32,
       max_value=512,
       step=32,
       default=128)

If you don't, hyperparameters always have a default default (for Int, it is equal to min_value).

Fixing values in a hypermodel

What if you want to do the reverse -- tune all available parameters in a hypermodel, except one (the learning rate)?

Pass a hyperparameters argument with a Fixed entry (or any number of Fixed entries), and specify tune_new_entries=True.

hypermodel = HyperXception(input_shape=(128, 128, 3), classes=10)

hp = HyperParameters()
hp.Fixed('learning_rate', value=1e-4)

tuner = Hyperband(
    hypermodel,
    hyperparameters=hp,
    tune_new_entries=True,
    objective='val_accuracy',
    max_epochs=40,
    directory='my_dir',
    project_name='helloworld')

tuner.search(x, y,
             validation_data=(val_x, val_y))

Overriding compilation arguments

If you have a hypermodel for which you want to change the existing optimizer, loss, or metrics, you can do so by passing these arguments to the tuner constructor:

hypermodel = HyperXception(input_shape=(128, 128, 3), classes=10)

tuner = Hyperband(
    hypermodel,
    optimizer=keras.optimizers.Adam(1e-3),
    loss='mse',
    metrics=[keras.metrics.Precision(name='precision'),
             keras.metrics.Recall(name='recall')],
    objective='val_precision',
    max_epochs=40,
    directory='my_dir',
    project_name='helloworld')

tuner.search(x, y,
             validation_data=(val_x, val_y))

Citation

BibTex entry:

@misc{omalley2019kerastuner,
	title        = {Keras {Tuner}},
	author       = {O'Malley, Tom and Bursztein, Elie and Long, James and Chollet, Fran\c{c}ois and Jin, Haifeng and Invernizzi, Luca and others},
	year         = 2019,
	howpublished = {\url{https://github.com/keras-team/keras-tuner}}
}

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